/*
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
 * You may obtain a copy of the License at:
 *
 *     http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */


#ifndef OVN_UTIL_H
#define OVN_UTIL_H 1

#include "openvswitch/meta-flow.h"
#include "ovsdb-idl.h"
#include "lib/bitmap.h"
#include "lib/packets.h"
#include "lib/sset.h"
#include "lib/svec.h"
#include "include/ovn/version.h"

#define ovn_set_program_name(name) \
    ovs_set_program_name(name, OVN_PACKAGE_VERSION)

#define ovn_print_version(MIN_OFP, MAX_OFP) \
    ovs_print_version(MIN_OFP, MAX_OFP)

#define ROUTE_ORIGIN_CONNECTED "connected"
#define ROUTE_ORIGIN_STATIC "static"
#define ROUTE_ORIGIN_LB "loadbalancer"

#define ETH_CRC_LENGTH 4
#define ETHERNET_OVERHEAD (ETH_HEADER_LEN + ETH_CRC_LENGTH)

#define GENEVE_TUNNEL_OVERHEAD 38
#define VXLAN_TUNNEL_OVERHEAD 30

struct eth_addr;
struct nbrec_logical_router;
struct nbrec_logical_router_port;
struct ovsrec_flow_sample_collector_set_table;
struct sbrec_datapath_binding;
struct sbrec_logical_flow;
struct sbrec_port_binding;
struct smap;
struct svec;
struct uuid;
struct unixctl_conn;
struct rconn;

struct ipv4_netaddr {
    ovs_be32 addr;            /* 192.168.10.123 */
    ovs_be32 mask;            /* 255.255.255.0 */
    ovs_be32 network;         /* 192.168.10.0 */
    unsigned int plen;        /* CIDR Prefix: 24. */

    char addr_s[INET_ADDRSTRLEN + 1];     /* "192.168.10.123" */
    char network_s[INET_ADDRSTRLEN + 1];  /* "192.168.10.0" */
    char bcast_s[INET_ADDRSTRLEN + 1];    /* "192.168.10.255" */
};

struct ipv6_netaddr {
    struct in6_addr addr;     /* fc00::1 */
    struct in6_addr mask;     /* ffff:ffff:ffff:ffff:: */
    struct in6_addr sn_addr;  /* ff02:1:ff00::1 */
    struct in6_addr network;  /* fc00:: */
    unsigned int plen;        /* CIDR Prefix: 64 */

    char addr_s[INET6_ADDRSTRLEN + 1];    /* "fc00::1" */
    char sn_addr_s[INET6_ADDRSTRLEN + 1]; /* "ff02:1:ff00::1" */
    char network_s[INET6_ADDRSTRLEN + 1]; /* "fc00::" */
};

struct lport_addresses {
    char ea_s[ETH_ADDR_STRLEN + 1];
    struct eth_addr ea;
    size_t n_ipv4_addrs;
    struct ipv4_netaddr *ipv4_addrs;
    size_t n_ipv6_addrs;
    struct ipv6_netaddr *ipv6_addrs;
};

static inline bool
ipv6_is_all_router(const struct in6_addr *addr)
{
    return ipv6_addr_equals(addr, &in6addr_all_routers);
}

static const struct in6_addr in6addr_all_site_routers = {{{
    0xff,0x05,0x00,0x00,0x00,0x00,0x00,0x00,
    0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x02
}}};

static inline bool
ipv6_is_all_site_router(const struct in6_addr *addr)
{
    return ipv6_addr_equals(addr, &in6addr_all_site_routers);
}

bool lrouter_is_enabled(const struct nbrec_logical_router *);
bool is_dynamic_lsp_address(const char *address);
bool extract_addresses(const char *address, struct lport_addresses *,
                       int *ofs);
bool extract_lsp_addresses(const char *address, struct lport_addresses *);
bool extract_ip_addresses(const char *address, struct lport_addresses *);
bool extract_ip_address(const char *address, struct lport_addresses *);
bool extract_lrp_networks(const struct nbrec_logical_router_port *,
                          struct lport_addresses *);
void lrp_network_to_string(const struct lport_addresses *, struct ds *,
                           bool include_generated_v6);
bool extract_sbrec_binding_first_mac(const struct sbrec_port_binding *binding,
                                     struct eth_addr *ea);

bool extract_lrp_networks__(char *mac, char **networks, size_t n_networks,
                            struct lport_addresses *laddrs);

bool lport_addresses_is_empty(const struct lport_addresses *);
void init_lport_addresses(struct lport_addresses *);
void destroy_lport_addresses(struct lport_addresses *);
const char *find_lport_address(const struct lport_addresses *laddrs,
                               const char *ip_s);

void split_addresses(const char *addresses, struct svec *ipv4_addrs,
                     struct svec *ipv6_addrs);

char *alloc_nat_zone_key(const char *name, const char *type);

const char *default_nb_db(void);
const char *default_sb_db(void);
const char *default_ic_nb_db(void);
const char *default_ic_sb_db(void);
const char *default_br_db(void);
char *get_abs_unix_ctl_path(const char *path);

struct ovsdb_idl_table_class;
const char *db_table_usage(struct ds *tables,
                           const struct ovsdb_idl_table_class *class,
                           int n_tables);

bool ovn_is_known_nb_lsp_type(const char *type);

/* The two pipelines in an OVN logical flow table. */
enum ovn_pipeline {
    P_IN,                       /* Ingress pipeline. */
    P_OUT                       /* Egress pipeline. */
};

uint32_t sbrec_logical_flow_hash(const struct sbrec_logical_flow *);
uint32_t ovn_logical_flow_hash(uint8_t table_id, enum ovn_pipeline pipeline,
                               uint16_t priority,
                               const char *match, const char *actions);
void ovn_conn_show(struct unixctl_conn *conn, int argc OVS_UNUSED,
                   const char *argv[] OVS_UNUSED, void *idl_);

void set_idl_probe_interval(struct ovsdb_idl *idl, const char *remote,
                            int interval);

#define OVN_MAX_DP_KEY ((1u << 24) - 1)
#define OVN_MAX_DP_GLOBAL_NUM ((1u << 16) - 1)
#define OVN_MIN_DP_KEY_LOCAL 1
#define OVN_MAX_DP_KEY_LOCAL (OVN_MAX_DP_KEY - OVN_MAX_DP_GLOBAL_NUM)
#define OVN_MIN_DP_KEY_GLOBAL (OVN_MAX_DP_KEY_LOCAL + 1)
#define OVN_MAX_DP_KEY_GLOBAL OVN_MAX_DP_KEY

#define OVN_MAX_DP_VXLAN_KEY ((1u << 12) - 1)
#define OVN_MAX_DP_VXLAN_KEY_LOCAL  ((1u << 10) - 1)
#define OVN_MIN_DP_VXLAN_KEY_GLOBAL (OVN_MAX_DP_VXLAN_KEY_LOCAL + 1)
#define OVN_MAX_DP_VXLAN_KEY_GLOBAL ((1u << 12) - 1)

#define OVN_MIN_EVPN_KEY (1u << 31)
#define OVN_MAX_EVPN_KEY (OVN_MAX_DP_GLOBAL_NUM | OVN_MIN_EVPN_KEY)

struct hmap;
void ovn_destroy_tnlids(struct hmap *tnlids);
bool ovn_add_tnlid(struct hmap *set, uint32_t tnlid);
bool ovn_tnlid_present(struct hmap *tnlids, uint32_t tnlid);
uint32_t ovn_allocate_tnlid(struct hmap *set, const char *name, uint32_t min,
                            uint32_t max, uint32_t *hint);
bool ovn_free_tnlid(struct hmap *tnlids, uint32_t tnlid);

static inline void
get_unique_lport_key(uint64_t dp_tunnel_key, uint64_t lport_tunnel_key,
                     char *buf, size_t buf_size)
{
    snprintf(buf, buf_size, "%"PRId64"_%"PRId64, dp_tunnel_key,
             lport_tunnel_key);
}

static inline void
get_mc_group_key(const char *mg_name, int64_t dp_tunnel_key,
                 struct ds *mg_key)
{
    ds_clear(mg_key);
    ds_put_format(mg_key, "%"PRId64"_%s", dp_tunnel_key, mg_name);
}

static inline void
get_sb_port_group_name(const char *nb_pg_name, int64_t dp_tunnel_key,
                       struct ds *sb_pg_name)
{
    ds_clear(sb_pg_name);
    ds_put_format(sb_pg_name, "%"PRId64"_%s", dp_tunnel_key, nb_pg_name);
}

char *ovn_chassis_redirect_name(const char *port_name);
char *ovn_mirror_port_name(const char *datapath_name,
                           const char *port_name);
void ovn_set_pidfile(const char *name);

bool ip46_parse_cidr(const char *str, struct in6_addr *prefix,
                     unsigned int *plen);
bool ip46_parse(const char *ip_str, struct in6_addr *ip);

char *normalize_ipv4_prefix(ovs_be32 ipv4, unsigned int plen);
char *normalize_ipv6_prefix(const struct in6_addr *ipv6, unsigned int plen);
char *normalize_v46_prefix(const struct in6_addr *prefix, unsigned int plen);
char *normalize_v46(const struct in6_addr *prefix);

/* Returns a lowercase copy of orig.
 * Caller must free the returned string.
 */
char *str_tolower(const char *orig);

long long ovn_smap_get_llong(const struct smap *smap, const char *key,
                             long long def);
bool ovn_str_to_ushort(const char *, int base, unsigned short *);

/* OVN daemon options. Taken from ovs/lib/daemon.h. */
#define OVN_DAEMON_OPTION_ENUMS                     \
    OVN_OPT_DETACH,                                 \
    OVN_OPT_NO_SELF_CONFINEMENT,                    \
    OVN_OPT_NO_CHDIR,                               \
    OVN_OPT_OVERWRITE_PIDFILE,                      \
    OVN_OPT_PIDFILE,                                \
    OVN_OPT_MONITOR,                                \
    OVN_OPT_USER_GROUP

#define OVN_DAEMON_LONG_OPTIONS                                              \
        {"detach",            no_argument, NULL, OVN_OPT_DETACH},            \
        {"no-self-confinement", no_argument, NULL,                           \
         OVN_OPT_NO_SELF_CONFINEMENT},                                       \
        {"no-chdir",          no_argument, NULL, OVN_OPT_NO_CHDIR},          \
        {"pidfile",           optional_argument, NULL, OVN_OPT_PIDFILE},     \
        {"overwrite-pidfile", no_argument, NULL, OVN_OPT_OVERWRITE_PIDFILE}, \
        {"monitor",           no_argument, NULL, OVN_OPT_MONITOR},           \
        {"user",              required_argument, NULL, OVN_OPT_USER_GROUP}

#define OVN_DAEMON_OPTION_HANDLERS                  \
        case OVN_OPT_DETACH:                        \
            set_detach();                           \
            break;                                  \
                                                    \
        case OVN_OPT_NO_SELF_CONFINEMENT:           \
            daemon_disable_self_confinement();      \
            break;                                  \
                                                    \
        case OVN_OPT_NO_CHDIR:                      \
            set_no_chdir();                         \
            break;                                  \
                                                    \
        case OVN_OPT_PIDFILE:                       \
            ovn_set_pidfile(optarg);                \
            break;                                  \
                                                    \
        case OVN_OPT_OVERWRITE_PIDFILE:             \
            ignore_existing_pidfile();              \
            break;                                  \
                                                    \
        case OVN_OPT_MONITOR:                       \
            daemon_set_monitor();                   \
            break;                                  \
                                                    \
        case OVN_OPT_USER_GROUP:                    \
            daemon_set_new_user(optarg);            \
            break;

#define OVN_DAEMON_OPTION_CASES                     \
        case OVN_OPT_DETACH:                        \
        case OVN_OPT_NO_SELF_CONFINEMENT:           \
        case OVN_OPT_NO_CHDIR:                      \
        case OVN_OPT_PIDFILE:                       \
        case OVN_OPT_OVERWRITE_PIDFILE:             \
        case OVN_OPT_MONITOR:                       \
        case OVN_OPT_USER_GROUP:

bool ip_address_and_port_from_lb_key(const char *key, char **ip_address,
                                     struct in6_addr *ip, uint16_t *port,
                                     int *addr_family);

/* Returns the internal OVN version. The caller must free the returned
 * value. */
char *ovn_get_internal_version(void);

/* OVN Packet definitions. These may eventually find a home in OVS's
 * packets.h file. For the time being, they live here because OVN uses them
 * and OVS does not.
 */

#define SCTP_INIT_CHUNK_LEN 16
struct sctp_16aligned_init_chunk {
    ovs_16aligned_be32 initiate_tag;
    ovs_16aligned_be32 a_rwnd;
    ovs_be16 num_outbound_streams;
    ovs_be16 num_inbound_streams;
    ovs_16aligned_be32 initial_tsn;
};
BUILD_ASSERT_DECL(
    SCTP_INIT_CHUNK_LEN == sizeof(struct sctp_16aligned_init_chunk)
);

/* These are the only SCTP chunk types that OVN cares about.
 * There is no need to define the other chunk types until they are
 * needed.
 */
#define SCTP_CHUNK_TYPE_INIT  1
#define SCTP_CHUNK_TYPE_ABORT 6

/* See RFC 4960 Sections 3.3.7 and 8.5.1 for information on this flag. */
#define SCTP_ABORT_CHUNK_FLAG_T (1 << 0)

/* The number of tables for the ingress and egress pipelines. */
#define LOG_PIPELINE_INGRESS_LEN 33
#define LOG_PIPELINE_EGRESS_LEN 15

static inline uint32_t
hash_add_in6_addr(uint32_t hash, const struct in6_addr *addr)
{
    for (uint8_t i = 0; i < 4; i++) {
#ifdef s6_addr32
        hash = hash_add(hash, addr->s6_addr32[i]);
#else
        uint8_t index = i * 4;
        uint32_t part = (uint32_t) addr->s6_addr[index]
            | (uint32_t) addr->s6_addr[index + 1] << 8
            | (uint32_t) addr->s6_addr[index + 2] << 16
            | (uint32_t) addr->s6_addr[index + 3] << 24;
        hash = hash_add(hash, part);
#endif
    }
    return hash;
}

/* Tunnel types ordered from most-preferred (higher number) to
 * least-preferred (lower number). */
enum chassis_tunnel_type {
    TUNNEL_TYPE_INVALID = -1,
    VXLAN  = 0,
    GENEVE = 1
};

enum chassis_tunnel_type get_tunnel_type(const char *name);

struct ovsrec_bridge_table;
const struct ovsrec_bridge *get_bridge(const struct ovsrec_bridge_table *,
                                       const char *br_name);

void daemon_started_recently_countdown(void);
void daemon_started_recently_ignore(void);
bool daemon_started_recently(void);
int64_t daemon_startup_ts(void);

char *lr_lb_address_set_name(uint32_t lr_tunnel_key, int addr_family);
char *lr_lb_address_set_ref(uint32_t lr_tunnel_key, int addr_family);

const char *
get_chassis_external_id_value(const struct smap *,
                              const char *chassis_id,
                              const char *option_key,
                              const char *def);
int
get_chassis_external_id_value_int(const struct smap *,
                                  const char *chassis_id,
                                  const char *option_key,
                                  int def);
unsigned int
get_chassis_external_id_value_uint(const struct smap *,
                                   const char *chassis_id,
                                   const char *option_key,
                                   unsigned int def);
unsigned long long int
get_chassis_external_id_value_ullong(const struct smap *external_ids,
                                     const char *chassis_id,
                                     const char *option_key,
                                     unsigned long long int def);
bool
get_chassis_external_id_value_bool(const struct smap *,
                                   const char *chassis_id,
                                   const char *option_key,
                                   bool def);

/* flow_collector_ids is a helper struct used to store and lookup
 * Flow_Sample_Collector_Set ids. */
struct flow_collector_id {
    struct ovs_list node;  /* In flow_collector_ids->list */
    uint64_t id;
};
struct flow_collector_ids {
    struct ovs_list list;
};
void flow_collector_ids_init(struct flow_collector_ids *);
void flow_collector_ids_init_from_table(struct flow_collector_ids *,
    const struct ovsrec_flow_sample_collector_set_table *);
void flow_collector_ids_add(struct flow_collector_ids *, uint64_t);
bool flow_collector_ids_lookup(const struct flow_collector_ids *, uint32_t);
void flow_collector_ids_destroy(struct flow_collector_ids *);
void flow_collector_ids_clear(struct flow_collector_ids *);

/* The DNS format is 2 bytes longer than the "domain".
 * It replaces every '.' with len of the next name.
 * The returned pointer has to be freed by caller. */
char *encode_fqdn_string(const char *fqdn, size_t *len);

/* Corresponds to each Port_Binding.type. */
enum en_lport_type {
    LP_UNKNOWN,
    LP_VIF,
    LP_CONTAINER,
    LP_MIRROR,
    LP_PATCH,
    LP_L3GATEWAY,
    LP_LOCALNET,
    LP_LOCALPORT,
    LP_L2GATEWAY,
    LP_VTEP,
    LP_CHASSISREDIRECT,
    LP_VIRTUAL,
    LP_EXTERNAL,
    LP_REMOTE
};

enum en_lport_type get_lport_type(const struct sbrec_port_binding *);
char *get_lport_type_str(enum en_lport_type lport_type);

/* A wrapper that holds sorted arrays of strings. */
struct sorted_array {
    const char **arr;
    bool owns_array;
    size_t n;
};

static inline struct sorted_array
sorted_array_create(const char **sorted_data, size_t n, bool take_ownership)
{
    return (struct sorted_array) {
        .arr = sorted_data,
        .owns_array = take_ownership,
        .n = n,
    };
}

static inline void
sorted_array_destroy(struct sorted_array *a)
{
    if (a->owns_array) {
        free(a->arr);
    }
}

static inline struct sorted_array
sorted_array_from_svec(struct svec *v)
{
    svec_sort(v);
    return sorted_array_create((const char **) v->names, v->n, false);
}

static inline struct sorted_array
sorted_array_from_sset(struct sset *s)
{
    return sorted_array_create(sset_sort(s), sset_count(s), true);
}

static inline int
name_cmp(const void *s1_, const void *s2_)
{
    const char *s1 = *(char **) s1_;
    const char *s2 = *(char **) s2_;
    return strcmp(s1, s2);
}

static inline struct sorted_array
sorted_array_from_unsorted(const char **unsorted_data, size_t n,
                           bool take_ownership)
{
    qsort(unsorted_data, n, sizeof *unsorted_data, name_cmp);
    return sorted_array_create(unsorted_data, n, take_ownership);
}

/* DB set columns are already sorted, just wrap them into a sorted array. */
#define sorted_array_from_dbrec(dbrec, column)           \
    sorted_array_create((const char **) (dbrec)->column, \
                        (dbrec)->n_##column, false)

void sorted_array_apply_diff(const struct sorted_array *a1,
                             const struct sorted_array *a2,
                             void (*apply_callback)(const void *arg,
                                                    const char *item,
                                                    bool add),
                             const void *arg);

/* */
struct dynamic_bitmap {
    unsigned long *map;
    size_t n_elems;
    size_t capacity;
};

static inline unsigned long *
ovn_bitmap_realloc(unsigned long *bitmap, size_t n_bits_old,
                   size_t n_bits_new)
{
    ovs_assert(n_bits_new >= n_bits_old);

    if (bitmap_n_bytes(n_bits_old) == bitmap_n_bytes(n_bits_new)) {
        return bitmap;
    }

    bitmap = xrealloc(bitmap, bitmap_n_bytes(n_bits_new));
    /* Set the unitialized bits to 0 as xrealloc doesn't initialize the
     * added memory. */
    size_t delta = BITMAP_N_LONGS(n_bits_new) - BITMAP_N_LONGS(n_bits_old);
    memset(&bitmap[BITMAP_N_LONGS(n_bits_old)], 0, delta * sizeof *bitmap);

    return bitmap;
}

static inline void
dynamic_bitmap_alloc(struct dynamic_bitmap *db, size_t n_elems)
{
    db->map = bitmap_allocate(n_elems);
    db->capacity = n_elems;
    db->n_elems = 0;
}

static inline void
dynamic_bitmap_free(struct dynamic_bitmap *db)
{
    bitmap_free(db->map);
}

static inline void
dynamic_bitmap_realloc(struct dynamic_bitmap *db, size_t new_n_elems)
{
    if (new_n_elems > db->capacity) {
        db->map = ovn_bitmap_realloc(db->map, db->capacity, new_n_elems);
        db->capacity = new_n_elems;
    }
}

static inline bool
dynamic_bitmap_is_empty(const struct dynamic_bitmap *db)
{
    return !db->n_elems;
}

static inline int
dynamic_bitmap_get_n_elems(const struct dynamic_bitmap *db)
{
    return db->n_elems;
}

static inline bool
dynamic_bitmap_is_set(const struct dynamic_bitmap *db, size_t offset)
{
    return bitmap_is_set(db->map, offset);
}

static inline size_t
dynamic_bitmap_count1(const struct dynamic_bitmap *db)
{
    return bitmap_count1(db->map, db->capacity);
}

static inline void
dynamic_bitmap_set1(struct dynamic_bitmap *db, int index)
{
    ovs_assert(index < db->capacity);
    if (!dynamic_bitmap_is_set(db, index)) {
        bitmap_set1(db->map, index);
        db->n_elems++;
    }
}

static inline void
dynamic_bitmap_set0(struct dynamic_bitmap *db, int index)
{
    ovs_assert(index < db->capacity);
    if (dynamic_bitmap_is_set(db, index)) {
        bitmap_set0(db->map, index);
        db->n_elems--;
    }
}

static inline void
dynamic_bitmap_or(struct dynamic_bitmap *db,
                  const unsigned long *arg, size_t n)
{
    ovs_assert(db->capacity == n);
    bitmap_or(db->map, arg, n);
}

static inline unsigned long *
dynamic_bitmap_clone_map(const struct dynamic_bitmap *db)
{
    return bitmap_clone(db->map, db->capacity);
}

static inline bool
dynamic_bitmap_equal(const struct dynamic_bitmap *a,
                     const struct dynamic_bitmap *b)
{
    return bitmap_equal(a->map, b->map, MIN(a->capacity, b->capacity));
}

static inline void
dynamic_bitmap_clone_from_db(struct dynamic_bitmap *dst,
                             const struct dynamic_bitmap *orig)
{
    if (dst->map) {
        bitmap_free(dst->map);
    }
    dst->map = dynamic_bitmap_clone_map(orig);
    dst->n_elems = dynamic_bitmap_count1(orig);
    dst->capacity = orig->capacity;
}

static inline size_t
dynamic_bitmap_scan(struct dynamic_bitmap *dp, bool target, size_t start)
{
    return bitmap_scan(dp->map, target, start, dp->capacity);
}

#define DYNAMIC_BITMAP_FOR_EACH_1(IDX, MAP)   \
        BITMAP_FOR_EACH_1(IDX, (MAP)->capacity, (MAP)->map)


static inline const char *
strip_leading_zero(const char *s)
{
    return s + strspn(s, "0");
}

static inline bool
is_uuid_with_prefix(const char *uuid)
{
     return uuid[0] == '0' && (uuid[1] == 'x' || uuid[1] == 'X');
}

bool is_partial_uuid_match(const struct uuid *uuid, const char *match);

/* Utilities around properly handling exit command. */
struct ovn_exit_args {
    struct unixctl_conn **conns;
    size_t n_conns;
    bool exiting;
    bool restart;
};

void ovn_exit_command_callback(struct unixctl_conn *conn, int argc,
                               const char *argv[], void *exit_args_);
void ovn_exit_args_finish(struct ovn_exit_args *exit_args);

bool ovn_update_swconn_at(struct rconn *swconn, const char *target,
                          int probe_interval, const char *where);

bool prefix_is_link_local(const struct in6_addr *prefix, unsigned int plen);

bool find_prefix_in_set(const struct in6_addr *prefix, unsigned int plen,
                        const struct sset *prefix_set,
                        const char *filter_name);

void ovn_debug_commands_register(void);

bool ovn_is_valid_vni(int64_t vni);

const struct sbrec_port_binding *lport_lookup_by_name(
    struct ovsdb_idl_index *sbrec_port_binding_by_name,
    const char *name);

void put_load_bytes(const void *value, size_t len, enum mf_field_id dst,
                    size_t ofs, size_t n_bits, struct ofpbuf *ofpacts);
void put_load(uint64_t value, enum mf_field_id dst, size_t ofs, size_t n_bits,
              struct ofpbuf *ofpacts);

/* __NARG__ provides a way to count the number of arguments passed to a
 * variadic macro. As defined below, it's capable of counting up to
 * 16 arguments. This should be more than enough for our purposes. However
 * the __ARG_N and __RSEQ_N macros can be updated to include more numbers
 * if we wish to be able to count higher.
 * */
#define __NARG__(...)  __NARG_I_(__VA_ARGS__,__RSEQ_N())
#define __NARG_I_(...) __ARG_N(__VA_ARGS__)
#define __ARG_N( \
      _1, _2, _3, _4, _5, _6, _7, _8, _9, \
      _10, _11, _12, _13, _14, _15, _16, N,...) N
#define __RSEQ_N() \
     16, 15, 14, 13, 12, 11, 10, 9, 8, 7, 6, 5, 4, 3, 2, 1, 0

/* VFUNC provides a way to overload macros so that they can
 * accept a variable number of arguments.
 *
 * It works by using __NARG__ to count the number of arguments
 * that were passed into the macro. Then this is concatenated
 * to the end of the macro name. Then this concatenated macro
 * is called.
 *
 * As an example, let's say we have
 * # define FOO(...) VFUNC(FOO, __VA_ARGS)
 *
 * Then if a caller were to call FOO(bar)
 * then we would count one argument (bar), concatenate
 * the 1 to the end of FOO, and end up calling FOO1(bar).
 *
 * If a caller were to call FOO(bar, baz), then the
 * result would be to call FOO2(bar, baz).
 */
#define _VFUNC_(name, n) name##n
#define _VFUNC(name, n) _VFUNC_(name, n)
#define VFUNC(func, ...) _VFUNC(func, __NARG__(__VA_ARGS__)) (__VA_ARGS__)

bool datapath_get_nb_uuid_and_type(const struct sbrec_datapath_binding *sb,
                                   struct uuid *nb_uuid, const char **type);

bool datapath_get_nb_uuid(const struct sbrec_datapath_binding *sb,
                          struct uuid *nb_uuid);

const char *datapath_get_nb_type(const struct sbrec_datapath_binding *sb);

struct sset *lrp_network_sset(const char **networks, int n_networks);

char *normalize_ipv4_prefix_str(const char *orig_prefix);

char *normalize_ipv6_prefix_str(const char *orig_prefix);

char *normalize_prefix_str(const char *orig_prefix);

char *normalize_ipv4_addr_str(const char *orig_addr);

char *normalize_ipv6_addr_str(const char *orig_addr);

char *normalize_addr_str(const char *orig_addr);

#define NEIGH_REDISTRIBUTE_MODES    \
    NEIGH_REDISTRIBUTE_MODE(FDB, 0) \
    NEIGH_REDISTRIBUTE_MODE(IP, 1)

enum neigh_redistribute_mode_bits {
#define NEIGH_REDISTRIBUTE_MODE(PROTOCOL, BIT) NRM_##PROTOCOL##_BIT = BIT,
    NEIGH_REDISTRIBUTE_MODES
#undef NEIGH_REDISTRIBUTE_MODE
};

enum neigh_redistribute_mode {
    NRM_NONE = 0,
#define NEIGH_REDISTRIBUTE_MODE(PROTOCOL, BIT)  \
    NRM_##PROTOCOL = (1 << NRM_##PROTOCOL##_BIT),
    NEIGH_REDISTRIBUTE_MODES
#undef NEIGH_REDISTRIBUTE_MODE
};

#define NEIGH_REDISTRIBUTE_MODE(PROTOCOL, BIT)          \
    static inline bool nrm_mode_##PROTOCOL##_is_set(    \
            enum neigh_redistribute_mode value)         \
    {                                                   \
        return !!(value & NRM_##PROTOCOL);             \
    }
NEIGH_REDISTRIBUTE_MODES
#undef NEIGH_REDISTRIBUTE_MODE

enum neigh_redistribute_mode
parse_neigh_dynamic_redistribute(const struct smap *options);

#endif /* OVN_UTIL_H */
